Fluorine-oxygen exchange reactions in iodine pentafluoride

This article is cited by 2 publications. Karl O. Christe,, William W. Wilson,, David A. Dixon, and, Jerry A. Boatz. . Journal of the American Chemical...
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Inorg. Chem. 1989, 28, 904-908

904

Contribution from Rocketdyne, A Division of Rockwell International, Canoga Park, California 91303

Fluorine-Oxygen Exchange Reactions in IF5, IF7, and IFSO Karl 0. Christe,* William W. Wilson, and Richard D. Wilson Received June 7, 1988 When reacted with alkali-metal nitrates, IF, readily exchanges two fluorine ligands for a doubly bonded oxygen atom. In all cases MIF40 salts (M = Li, K, Cs) and FNO, are formed as the primary products. The FNO, byproduct undergoes a fast secondary reaction with MNO, to yield equimolar amounts of N20Sand MF. The N205decomposes to N2O4 and 0.5 mol of 0,. while the MF, depending on the nature of M, does or does not undergo complexation with the excess of IF,. Pure MIF40 salts, free of and IF, in either CH$N or IF, as a solvent. The new compounds MF or MF.nIF5 byproducts, were prepared from MF, 1205, LiIF,O, NaIF40, RbIF40, and NOIF40 were characterized by vibrational spectroscopy. It was also shown that, contrary to a previous report, FNO2 does not form a stable adduct with IF, at temperatures as low as -78 "C. An excess of IF7 reacts with but surprisingly no IFSO. With CsNO,, the reaction products MNO, (M = Li, Na) to give MF, FNO,, IF,, and 0.5 mol of 02, are analogous, except for the CsF reacting with both the IF, product and the excess of IF7 to give CsIF&!IF, and CsIF8, respectively. When in the IF7 reaction an excess of LiNO,, is used, the IF, product undergoes further reaction with LiNO,, as described above. The IF,O molecule was found to be rather unreactive. It does not react with either LiF or CsF at 25 or 60 OC or with LiNO, or CsNO, at 25 "C. At 60 "C with UNO,, it slowly loses oxygen, with the IF, product reacting to yield LiIF40, as described above.

Introduction Recent work from our laboratory has shown that the nitrate ion is an excellent reagent for replacing two fluorine ligands by one doubly bonded oxygen atom in compounds such as BrFs,l.z XeF6? and XeOF4.4 A logical extension of this work was a study of analogous fluorine-oxygen exchange reactions in iodine

fluorides. Although the reaction of KN03 with a large excess of IFSa t its boiling point has previously been reporteds to yield NOz and KIF6, no mention of any fluorine-oxygen exchange was made. Some evidence for hydrolytic fluorine-oxygen exchange in &IF6 was observed during its recrystallization from CH3CN solution. It resulted in the isolation of small amounts of single crystals of CsIF40, which were used for a crystal structure determinatione6 Attempts to utilize this reaction or the reactions of either MI03 or MI02F2(M = K or Cs) with IFs for the preparation of MIF40 salts, however, resulted only in mixtures of MIF40 and MIOzFz.7 Finally, pure KIF40 was prepared from a 5:l mixture of KF1205 in a large excess of IF5, and its vibrational spectra have been recorded.8 In the case of IF7,fluorine-oxygen exchange has been achieved by its reaction with either silica at 100 O C ? Cab-0-Si1 at ambient temperature,I0 or Pyrex,llJz IzOs,12 or small amounts of water"-I3 at room temperature with IF50being the principal product. Most likely, the reactions with silica or Pyrex also involve the hydrolysis of IF7, with traces of HF continuously regenerating the required HzO according to (1) and (2). However, most of these reactions Si02 + 4HF

IF7

+ H20

-

-

SiF4 + 2 H z 0

(1)

IF50 + 2 H F

are slow and are difficult to control and scale up. It was, therefore, (1) Wilson, W. W.; Christe, K. 0. Inorg. Chem. 1987, 26, 916. (2) Wilson, W. W.; Christe, K. 0. Inorg. Chem. 1987, 26, 1573. (3) Christe, K. 0.;Wilson, W. W. Inorg. Chem. 1988, 27, 1296. (4) Christe, K. 0.;Wilson, W. W. Inorg. Chem., in press. ( 5 ) Aynsley, E.E.; Nichols, R.; Robinson, P. L. J . Chem. SOC.1953,623. (6) Ryan, R. R.; Asprey, L. B. Acta Crystallogr. 1972, 828, 979. (7) Milne, J. B.; Moffett, D. M. Inorg. Chem. 1976, 15, 2165. (8) Christe, K. 0.;Wilson, R. D.; Curtis, E. C.; Kuhlmann, W.; Sawodny, W. Inorg. Chem. 1978, 17, 533. (9) Gillespie, R. J.; Quail, J. W. Proc. Chem. SOC.1963, 278. (10) Schack, C. J.; Pilipovich, D.; Cohz, S. N.; Sheehan, D. F. J. Phys. Chem. 1968, 72,4697. (1 1) Alexakos, L. G.; Cornwell, C. D.; Pierce, S. B. Proc. Chem. Soc. 1963, 341. (12) Bartlett, N.; Levchuk, L. E. Proc. Chem. Soc. 1963, 342. (13) Selig, H.; Elgad, U. J . Inorg. Nucl. Chem. Suppl. 1976, 91. 0020-1669/89/1328-0904$01.50/0

interesting to examine whether nitrates could be used advantageously to achieve fluorine-oxygen exchange in iodine fluorides and to prepare new iodine oxyfluoride salts.

Experimental Section Apparatw and Materials. The vacuum lines, handling techniques, and spectrometers used in this study have been described elsewhere., Commercial LiNO, (J. T. Baker, 99.7%), NaN0, (J. T. Baker 99.5%) and KNO, (J. T. Baker, 99.1%) were dried in vacuo at 120 OC for 1 day prior to their use. The CsNO, were prepared from Cs2C0, and HNO, and dried in the same manner. The heavier alkali-metal fluorides (K, Rb, Cs) were dried by fusion in a platinum crucible and powdered in a drybox prior to use, while the lighter ones (Li, Na) were dried in vacuo at 120 "C. The N205,14FN02,' FN0,15 IF7,I0and IF,O,10 were prepared by literature methods. The IF, (Matheson Co.) was treated with CIF, (Matheson) at 25 OC until the originally dark brown liquid was colorless. Pure IF, was obtained by fractional condenation at -64 OC in a dynamic vacuum. A commercial sample of 1205(Mallinckrodt), which actually was HI,08, was converted to 1205by heating to 210 OC in a dynamic vacuum for 12 h. Its purity was verified by Raman spectroscopy.I6 The CH$N (Baker, UV grade,